Upload
votu
View
237
Download
0
Embed Size (px)
Citation preview
1
Chapter 1: Introduction
Forensic archaeology is a relatively new sub-discipline of archaeology that emerged out
of the potential to apply systematic archaeological excavation and recording to the
investigation and research of crime scenes and the recovery of human remains deposited
through clandestine activities (Hunter et al., 1994: 758). In its developed form it can be
defined as a sub-disciple of archaeology that involves the application of archaeological
techniques and theories to assist in the process of a forensic investigation by providing
evidence for use in legal proceedings (Darvill 2008: 162). Over the past decade this sub-
discipline has gained credibility internationally, through the realisation that the
utilisation of archaeologists in forensic investigations resulted in an improved rate of
evidence recovery and documentation (Morse et al., 1976; Sigler-Eisenberg 1985; Crist
2001; Sonderman 2001; Davenport and Harrison 2011). Consequently, forensic
archaeologists are increasingly requested to participate in crime scene investigations
both nationally and internationally, the majority of which revolve around the recovery
of human remains from earth-cut graves.
Existing forensic archaeological literature is dominated by papers and reports that have
been written by practitioners both in the academic and commercial sectors of the
discipline. These have discussed the sub-field’s development and the application of
forensic archaeological techniques to various types and stages of forensic investigation,
in particular, the excavation and recording of single and mass burials (Vanezis 1999;
Haglund 2001; Haglund et al., 2001; Owsley 2001; Ferllini 2003; Blau 2004; Blau
2005; Blau and Skinner 2005; Hunter and Cox 2005; Oakley 2005; Connor 2007;
Schultz and Dupras 2008; Blau and Ubelaker 2009). Whilst such publications are
mostly of the same opinion regarding the value of forensic archaeology in domestic and
international contexts, the question of forensic excavation and recording methodology is
more divided, with scholars advocating different approaches to the examination of
similar types of feature such as pits, ditches, and graves.
The greatest divergence relates to the excavation of single or mass graves. Some
practitioners advocate various forms of the Arbitrary Excavation method (Bass and
Birkby 1978; Morse et al., 1983; Brooks and Brooks 1984; Ubelaker 1989;
Spennemann and Franke 1995; Pickering and Bachman 1997; Haglund et al., 2001;
Stover and Ryan 2001; Oakley 2005; Burns 2006; Ruwanpura et al., 2006 and Connor
2
2007). Other practitioners suggest that a form of Block Excavation be used (Larson et
al., 2011). In contrast, some scholars state that graves should be excavated using a form
of sectioning, suggesting that either the Demirant or Quadrant Excavation methods be
used (Hunter and Cox 2005; Dupras et al., 2006; Congram 2008; Hunter 2009 and
Ruffell et al., 2009; Hunter et al., 2013). Alternatively, Wolfe Steadman et al., (2009)
advocate a Vertical Slice Excavation method. Many other academics recommend that
graves should be excavated using the Stratigraphic Excavation method (Powell et al.,
1997; Connor and Scott 2001; Hunter et al., 2001; Hochrein 2002; Skinner et al., 2003;
Hanson 2004; Blau 2005; Blau and Skinner 2005; Jessee and Skinner 2005; Skinner and
Sterenberg 2005; Schultz and Dupras 2008; Cheetham and Hanson 2009, and Nuzzolese
and Borrini 2010).
These divergences emphasise the lack of standardisation in forensic archaeological
practice, a problem that can be attributed to the fact that forensic archaeological
practitioners have uncritically adopted techniques, principles, and practices from the
wider and long-established sub-discipline of field archaeology (Hunter et al., 1996;
Drewett 1999).
In the field of archaeology, approaches to archaeological excavation and recording vary
greatly from country to country, and have evolved to their current state according to the
practices advocated by practitioners and professional bodies in their country of origin,
and the inherited traditions present in each. Consequently, different excavation methods
and recording systems are used by different archaeological practitioners in accordance
with their individual preferences. These preferences, however, are largely determined
by the site types from which an archaeological practitioner has gained their academic
training and experience (Carver 2009; Carver 2011: 107). Thus, if an archaeologist had
gained their academic qualifications and field experience in North America, working
primarily on prehistoric burial sites lacking stratigraphy, they would be more likely to
advocate an Arbitrary method of excavation and a Unit Level method of recording
(Wheeler 1954; Pallis 1956; Willey and Sabloff 1980; Joukowsky 1980; Brooks and
Brooks 1984; Ubelaker 1989; Hester 1997; Hochrein 1997; Pickering and Bachman
1997; Powell et al., 1997; Drewett 2000a-e). Whereas, if an archaeologist had gained
their academic qualifications and field experience in the United Kingdom since 1980,
working primarily on urban cemetery sites with complex stratigraphy, they would be
3
more likely to advocate a Stratigraphic method of excavation and a Single Context
method of recording (Wheeler 1954; Pallis 1956; Praetzellis 1993; Harris 1979; Barker
1993; Hester 1997; Roskams 2001; Hanson 2004; Balme and Paterson 2006).
However, the adoption of a variety of different methodological approaches to the
excavation and recording of single or mass graves from field archaeology into forensic
archaeological practice poses a problem. The primary aim of forensic archaeological
investigations is the provision of evidence to legal proceedings. Therefore, when
archaeological investigations are conducted within a forensic context the methods
utilised, and the evidence retrieved as a consequence of the investigation are held
accountable to the admissibility regulations and the legal processes upheld by the courts
in the country in which the investigation is being conducted and/or tried.
In general, the legal processes and admissibility regulations state that any techniques
used during the course of a forensic investigation must have been subjected to empirical
testing, peer review, have known error rates, have standards controlling their operation,
and be widely accepted amongst the academic community from which they originate
(Pepper 2005; Glancy and Bradford 2007; Hanzlick 2007; Edwards 2009; Klinker 2009;
NAS Report 2009; The Law Commission 2009, 2011; Robertson 2009; Edmond 2010;
Robertson 2010; Selby 2010). Therefore, if an archaeologist is to be accepted as an
expert witness by legal practitioners, and the evidence retrieved as a consequence of an
archaeological investigation is to be accepted by a court, the archaeologist must be able
to demonstrate that the methods utilised during the course of the forensic archaeological
investigation adhered to a widely accepted and tested archaeological investigatory
process (Hunter and Knupfer 1996: 37). However, to date, no such forensic
archaeological investigatory process has been established. Furthermore, no substantial
empirical testing has been undertaken regarding archaeological excavation methods or
recording systems, a point which was highlighted in a recent report published by the
‘Committee on Identifying the Needs of the Forensic Sciences Community, National
Research Council’ (NAS Report 2009). As a consequence, much of the work
undertaken through excavation by forensic archaeologists does not currently meet the
admissibility regulations and legal requirements of the international court systems.
It follows that for the sub-field of forensic archaeology to continue to maintain
credibility as a forensic discipline, it is necessary for the various archaeological
4
excavation methods and recording systems advocated by practitioners within the
archaeological literature to be empirically tested, error rates to be established, and a peer
reviewed protocol to be formulated. This will ensure that evidence gathered as a
consequence of a forensic archaeologist’s participation within a forensic investigation
will not be dismissed from future court proceedings as inadmissible.
1.1 Research question
Against this background, the central question at the heart of this research is: do
recognised archaeological excavation methods and recording systems used to recover
evidence in forensic cases satisfy the legal tests of admissibility currently applied in the
international courts?
1.2 Aim of the Research Project
The aim of this Project is to determine which, if any, of the various excavation methods
and recording systems currently used in the United Kingdom, Ireland, Australasia and
North America fulfil criteria for legal acceptance and best meet the needs of forensic
archaeology. Burials and the recovery of human remains are the focus of attention in
this research as these represent the majority of work in this sub-field, although the
research has wider implications.
1.3 Objectives of the Research Project
Experimental studies conducted by Chilcott and Deetz (1964), Tuller and Đurić (2006),
Pelling (2008), Evis (2009), Roberts (2009), and Scherr (2009) compared
archaeological excavation methods to determine the impact that different
methodological approaches had upon the retrieval of artefacts and the formulation of
interpretations regarding an archaeological feature’s formation process. In order to
expand upon these experimental studies, and to establish the most effective
archaeological excavation methods and recording systems to use during forensic
archaeological investigations the following objectives were pursued:
1. To review, analyse and compare published academic literature and
published/unpublished archaeological manuals/guidelines.
5
2. To identify the origins, development and current use of archaeological
excavation methods and recording systems in the United Kingdom, Ireland,
Australasia and North America.
3. To conduct interviews with field and academic archaeologists in order to
evaluate how they excavate, and why and when they choose to use particular
excavation methods and recording systems.
4. To create a controlled experiment through which differing archaeological
excavation methods, recording systems and the affect of archaeological
experience can be directly compared, contrasted and measured.
5. To examine the affect that factors such as archaeological excavation method,
archaeological recording system, and archaeological experience have on
archaeological investigations, including: the quality and quantity of evidence
recovered, and the consistency of interpretation(s) regarding the site’s formation
process.
1.4 Structure of the thesis
The thesis is divided into two volumes, the second of which contains the results of the
thesis. This unusual structure has been selected as the results chapters are particularly
large, and by placing the results in a separate volume, the reader will be able to view the
results with ease as they read the discussion chapters.
In Volume I Chapter 2, there is a literature review, in which four different subjects are
explored. The first subject is the development of archaeological excavation methods and
recording systems. The second subject is how archaeological excavation and recording
methods have been adapted and applied to forensic investigations. The third subject is
how the legal requirements of the international courts impact forensic archaeological
investigations, and the fourth subject is how forensic archaeological practitioners have
attempted to standardise forensic archaeological practice.
In Volume I Chapter 3, the methodological approaches used during the research in order
to achieve the five objectives outlined above are discussed.
6
Volume II Chapter 7.1, contains the results from the archaeological manual/guideline
analysis. These results are then explored in Volume I Chapter 4.1, in which the
development, origins and current use of archaeological excavation methods and
recording systems in the United Kingdom, Ireland, Australasia, and North America are
discussed.
Volume II Chapter 7.2, contains the results of the interviews conducted with
archaeological practitioners. These interview results are then used, in Volume I Chapter
4.2, to answer how archaeological practitioners excavate, and explain why and when
archaeologists choose to use particular excavation methods and recording systems.
Volume II Chapter 8 and Volume II Chapter 8.1, contains the results of the grave
excavation experiments. These results are first explored in Volume I Chapter 4.3, in
which each of the excavation methods and recording systems tested are comparatively
assessed, in order to determine how the different methodological approaches impacted
the quality and quantity of evidence recovered during the grave excavation experiments.
The results presented in Volume II Chapter 8, are also used to examine, in Volume I
Chapter 4.4, how the different methodological approaches tested impacted the
construction of interpretation-based narratives of the formation sequence of the grave
simulation.
The results presented in Volume II Chapter 8, are then used to explore, in Volume I
Chapter 4.5, the impact that the length of time that archaeologists spent conducting the
excavation experiment had on the quality and quantity of evidence recovered.
The results presented in Volume II Chapter 8, are finally used, in Volume I Chapter 4.6,
to discuss the impact that archaeological experience had on the quality and quantity of
evidence recovered during the grave excavation experiments.
In Volume I Chapter 4.7, the reasons why error rates are unable to be established for
archaeological excavation methods and recording systems are discussed.
In Volume I Chapter 5, the conclusions of the research are presented. These state which
of the excavation methods and recording systems tested best meets the needs of forensic
7
archaeology, and satisfies the legal and admissibility requirements of the international
courts.
Volume I Chapter 6, contains recommendations for future research in this subject area,
and highlights the methodological approaches that ought to be used by forensic
archaeologists when conducting forensic archaeological investigations.
8
Chapter 2: Background
2.1 The development and use of archaeological excavation
methods and recording systems
In order to examine the separate development and use of different archaeological
excavation methods and recording systems, it is necessary to discuss the underlying
theoretical principles, the practical application and the origins of the Stratigraphic
Excavation method, the Quadrant Excavation method, the Demirant Excavation method
and the Arbitrary Excavation method and their associated recording systems.
Archaeological excavation and recording
The processes of archaeological excavation and recording provide archaeologists with
the methodological tools by which they are able to retrieve and record archaeological
data that have been buried as a result of natural and/or man made processes (Clarke
1978; Barker 1993; Pavel 2010). This procedure is often referred to as a process of
controlled destruction, which provides archaeologists with a singular opportunity to
extract, define and record artefacts, features and stratigraphic units present within an
archaeological site (Barker 1993; Roskams 2001; Harris 2006; Carver 2009). Once
completed, this process allows archaeologists to formulate interpretations regarding the
human activities that occurred at the site during a particular period in the past and
changes in those activities through time (Harris 1989; Roskams 2001; Saul and Saul
2002).
Although the processes of archaeological excavation and recording are central to the
recovery and documentation of archaeological data in the field of archaeology,
methodological approaches vary internationally, with numerous archaeologists
advocating differing methodologies for the excavation and recording of the same type
of archaeological feature (Phillips et al., 1951; Wheeler 1954; Pallis 1956; Kjolbye-
Biddle 1975; Harris 1979; Joukowsky 1980; Barker 1993; Roskams 2001; Carver 2009;
Pavel 2010). This variation in methodological approaches is primarily due to the
differential development of archaeological practice internationally.
9
The development of Stratigraphic Excavation
The principle of stratigraphy was first conceptualised in the field of geology during the
eighteenth century by individuals such as Nicolaus Steno, William Smith and Sir
Charles Lyell (Steno 1669; Smith 1815; Smith 1816; Lyell 1830; Lyell 1832; Lyell
1833; Gardner 1997; Dirkmaat and Adovasio 1997; Hochrein 2002). These geologists
first recognised the concept of stratification; the process whereby geological layers of
strata are continually laid down over time in a series of sequential layers one on top of
the other (Renfrew 1973; Harris 1989; Barker 1993). Geological stratigraphy is the
overall study and validation of geological stratification with a view to arranging
geological strata into a chronological sequence (Renfrew 1973; Harris 1989; Barker
1993).
In archaeology, the process of stratification and the concept of stratigraphy is the same,
however, archaeological stratification differs in that strata present within an
archaeological site can be the result of both man made and/or natural processes (Harris
1989; Barker 1993). There are two types of archaeological stratigraphic unit. One is
referred to as a layer/deposit/fill and the other is known as an interface.
Layers/deposits/fills have a mass, a physical presence within the site, and have been
deposited within the site by either natural processes such as a flood, or anthropogenic
processes such as the construction of a floor or the infilling of a pit (Barker 1993; Harris
1989; 2002).
Interfaces are surfaces created as a result of the deposition of a layer/deposit/fill or by
the removal of an existing layer/deposit/fill. There are two types of interface – a vertical
interface and a horizontal interface (Harris 1989; 2002). Every layer/deposit/fill has two
interfaces, one above and one below (Barker 1993: 171). Unlike layers/deposits/fills,
such interfaces are not able to be excavated and removed from a site, and must be
recorded where they are found (Harris 1989; 2002; Dupras et al., 2006). Although the
deposition of a layer/deposit/fill and the creation of an interface can be seen as being
contemporaneous they are regarded and recorded as separate stratigraphic units, as there
are occasions when the formation of an interface and the deposition of a
layer/deposit/fill are not synchronous. A cut into existing layers/deposits/fills is an
example of such an occasion where, for example, a ditch has been cut into existing
10
layers of strata and has been left open and at a later point in time been filled in; thus the
creation of the ditch and the subsequent infilling are not contemporaneous and are
therefore recorded as separate stratigraphic units (Harris 1989; 2002; Roskams 2001).
The process by which archaeological stratification occurs is governed by the following
principles:
Principle Of Superposition: in a series of layers, as originally created, the upper units of
stratification are younger and the lower older, as each must have been deposited on, or
created as a result of the removal of, a pre-existing mass of archaeological stratification
(Harris 1989: 30).
Principle Of Original Horizontality: any layer deposited in an unconsolidated form will
tend towards a horizontal position; strata found with tilted surfaces were originally
deposited that way, or lie in conformity with the contours of a pre-existing basin of
deposition (Harris 1989: 31).
Principle Of Original Continuity: an archaeological layer as originally laid down, will
be bounded by a basin of deposition or will thin down to a feather edge. If any edge of
the layer is exposed in vertical view, part of its original context must have been
removed by excavation or erosion and its continuity must be sought or absence
explained (Harris 1989: 32).
Principle Of Stratigraphical Succession: any unit of archaeological stratification takes
its place in the stratigraphic sequence of a site from its position between the lowest of
all units which lie above it and the uppermost of all those units which lie below it and
with which it has physical contact (Harris and Reece 1979: 113; Harris 1989: 34).
Principle Of Intercutting: if a feature or a layer/deposit/fill is found to cut into, or
across, another layer/deposit/fill it must be more recent (Darvill 2008: 438).
Principle Of Incorporation: all artefactual and ecofactual material found to be contained
within a layer/deposit/fill must be the same age or older than the formation of that layer
(Darvill 2008: 438).
11
Principle Of Correlation: relationships can be inferred between layers/deposits/fills that
exhibit the same characteristics, contain the same range of artefactual and ecofactual
material, and occupy comparable stratigraphic positions within related stratigraphic
sequences (Darvill 2008: 438).
It is by adherence to these principles that Stratigraphic Excavation is conducted, during
which individual stratigraphic units, are excavated in their entirety, in the reverse order
in which they were deposited from the latest to the earliest, see Figure 2.1 (Harris 1989;
2002; Barker 1993; Darvill 2000; Turnbaugh et al., 2002). In addition, any finds or
samples retrieved during the excavation of a stratigraphic unit are recorded as
originating from the stratigraphic unit from which they were obtained (Darvill 2000:
32). When using this excavation technique, an archaeological recording system known
as Single Context Recording is used. When using this system of recording, each
stratigraphic unit that is identified during the excavation is planned and recorded in
three dimensions, as are any artefacts that were found or samples that were taken
(Darvill 2000: 32). Consequently, this process allows archaeologists to recover and
record the exact physical dimensions of each stratigraphic unit, and the relative
chronology of deposition of the individual stratigraphic units present within the
archaeological site (Harris 1989; 2002; Darvill 2000; Carver 2009). That, in turn,
enables archaeologists to determine the stratigraphic sequence of the archaeological site
(Harris 1989; 2002; Darvill 2000; Carver 2009). If the artefacts recovered during the
archaeological excavation can be allocated a specific date of manufacture, then it is
possible to allocate a terminus post quem or terminus ante quem for the relative
deposition of the stratigraphic units and the creation of archaeological features present
at the archaeological site (Harris 1989; 2002; Barker 1993).
The concept of Stratigraphic Excavation has long been recognised by archaeologists. As
early as the nineteenth century archaeologists such as J.J.A Worsaae excavating
Prehistoric sites in Denmark and Giuseppe Fiorelli excavating in Pompeii applied
stratigraphic approaches to their excavations (Gamble 2001: 61), realising as Droop
(1915:7-8) so eloquently phrased it – “if objects be taken out in a higgledy piggldey
manner no subsequent knowledge of the history of accumulations will be of much
avail”. However, widespread utilisation of the Stratigraphic method of excavation did
not occur until practitioners such as Geoffrey Wainwright excavated rural
12
archaeological sites at Tollard Royal and Gussage All Saints in Dorset, and Philip
Barker excavated urban archaeological sites at Wroxeter and Shropshire (Wainwright
1968; 1979; Barker et al., 1997; Darvill 2000: 32). Ever since, the Stratigraphic method
of excavation has been continually advocated by numerous scholars including Barker
(1997), Harris (1979; 1989; 2002), Roskams (2001), Hanson (2004) and Carver (2009)
to name but a few, and has now become somewhat standardised practice for
archaeological investigations conducted in the United Kingdom and Ireland.
The development of Quadrant and Demirant Excavation
The Quadrant Excavation method also adheres to the aforementioned principles of
archaeological stratigraphy, and is an excavation method that tends to be used to
excavate circular or negative archaeological features (Darvill 2000: 31; Carver 2009).
This excavation approach is applied by dividing the archaeological feature that is to be
excavated into four quarters (Atkinson 1946; Darvill 2000; Carver 2009). Subsequently,
each quarter is excavated individually, with two opposing quarters being excavated first,
as shown in Figure 2.2 (Atkinson 1946; Darvill 2000; Carver 2009). Occasionally,
when utilising this excavation method, archaeologists leave either a cross-shaped or
key-shaped baulk across the midline of the feature (Atkinson 1946; Darvill 2000;
Carver 2009). However, the manner in which this excavation approach is applied is
determined by the preferences of the archaeologist responsible for excavating the
archaeological feature.
When using the Quadrant Excavation method, the recording of the stratigraphic units
present relies not on plans, but on recording the long section and half section profiles
that are exposed during the excavation process (Atkinson 1946; Darvill 2000; Carver
2009). This enables the sequence of deposition across the entire archaeological feature
to be documented and reconstructed after the excavation has been completed.
Similarly, the Demirant Excavation method also adheres to the aforementioned
principles of archaeological stratigraphy, and is primarily used to excavate circular or
negative archaeological features that are too small in size for the Quadrant Excavation
method to be used. This excavation method is applied by first dividing the
archaeological feature that is to be excavated into two halves. Subsequently, each half is
excavated separately, as shown in Figure 2.3 (Carver 2009; Darvill 2008).
13
When using the Demirant Excavation system, the recording of stratigraphic units relies
on recording the half section face that is exposed once the first half of the
archaeological feature has been excavated (Carver 2009; Darvill 2008). This enables the
archaeologist to document the sequence of deposition of the stratigraphic units present,
at the particular point at which the half section was set up.
The use of sectioning as a method to excavate, record and interpret archaeological
features can be dated to the early 1920s and the work of Cyril Fox, who applied this
approach to his excavation of Bronze Age round barrows in Wales (Darvill 2000: 31).
Subsequently, these methodological approaches have continued to be used regularly in
field archaeology to deal with both circular and cut features in the United Kingdom,
Ireland and Continental Europe (Darvill 2000; Darvill 2008; Hunter and Cox 2005;
Dupras et al., 2006; Ruffell et al., 2009; Litherland et al., 2011).
The development of Arbitrary Excavation
The excavation method known as Arbitrary Excavation is also referred to by other
names including – the Unit Level method, the Planum technique and Metrical
Stratigraphy (Hester et al., 1997; Darvill 2000; Lucas 2001; Hanson 2004; Darvill 2008;
Carver 2009).
It is an excavation method whereby an archaeological site is divided into individual
excavation units, which are usually 1m x 1m in area (Darvill 2000: 31). The area within
these excavation units is then excavated in a succession of separate arbitrary levels,
each of which is completed before the next is excavated; such levels are usually 5cm,
10cm or 20cm in depth, see Figure 2.4 (Hester 1997:88; Darvill 2000). Each arbitrary
level is regarded as a separate unit of stratification and artefacts retrieved from each
arbitrary level are placed into a depositional sequence in relation to the arbitrary level
from which they were recovered, in accordance with the principle of superposition
(Hanson 2004; Darvill 2000). When using the Arbitrary Excavation method a recording
system known as Unit Level Recording is used. When using this system of recording,
archaeologists complete plans of each of the arbitrary levels that were excavated in
14
which any relevant soil colours, structures and deposits present are defined and drawn
(Hester 1997; Darvill 2000: 31).
The process of Arbitrary Excavation originated in the Americas in the early twentieth
century, as a result of the increased formalisation of American field archaeology and the
rejection of the formally dominant concept of evolutionism; the belief that non-
European peoples lacked any form of identifiable history (Lucas 2001). As a result,
increased emphasis was placed upon the retrieval of artefactual evidence from
archaeological sites, and the establishment of chronological sequences of material
culture assemblages associated with non-European cultures that had existed prior to the
European migration to the Americas in the fifteenth century (Willey and Sabloff 1980;
Browman and Givens 1996; Lyman and O’Brien 1999; Lucas 2001).
As chronological sequencing of material culture assemblages found at archaeological
sites came to dominate the concerns of American archaeologists, existing excavation
techniques were adapted in what has come to be referred to as the ‘stratigraphic
revolution’ in which the geological principles of stratification and stratigraphy became
widely utilised to interpret archaeological sites, and provided a method by which
archaeologists could contrast, compare and prove cross-site material culture sequences
(Willey and Sabloff 1980; Lucas 2001). However, unlike in the United Kingdom,
Ireland and continental Europe the methodological approaches used in order to
understand stratigraphic sequences differed, in that Stratigraphic Excavation usually
meant the recognition of evident stratification post-facto or via vertical section as the
excavation proceeded in arbitrary levels, rather than excavation by recognition and
adherence to identifiable stratigraphic units (Browman and Givens 1996; Lucas 2001).
The adoption of the Arbitrary ‘Stratigraphic’ Excavation approach has been attributed to
the American archaeologists - Nels C Nelson (1916) excavating in South Western
America and Manual Gamio (1930) excavating in Mexico. It is widely believed that
Nelson adopted this excavation approach after excavating for a season at Castillo in
Spain in 1913, during which he witnessed the process of Stratigraphic Excavation
(Browman and Givens 1996; Lucas 2001). Subsequently, when he returned to North
America it is thought that he was unsure of how to apply the Stratigraphic Excavation
method he had utilised in Castillo to his excavations at San Cristóbal (Browman and
Givens 1996; Lucas 2001). This resulted in Nelson setting up excavation units within
15
which he excavated using arbitrary one-foot levels and interpreted the stratigraphic
sequence via vertical section (Browman and Givens 1996; Lucas 2001).
This Arbitrary Excavation method, pioneered by Nelson, was subsequently adopted by
both North American and Latin American archaeologists as a standard excavation
method and continues to be advocated by archaeologists within American excavation
guidance literature (Brooks and Brooks 1984; Ubelaker 1989; Spennemann and Franke
1995; Browman and Givens 1996; Hester 1997).
Despite the widespread adoption of the Arbitrary Excavation methodology throughout
North and Latin America, not all practitioners utilised this method of excavation.
Archaeologists such as George Pepper, Alfred Kidder and Max Uhle preferred to
excavate using natural stratigraphy, excavating in accordance to the identifiable
stratigraphic boundaries present at archaeological sites (Browman and Givens 1996;
Lucas 2001), believing that excavating arbitrarily “would have resulted in the splitting
or cross-cutting of strata” (Kidder and Kidder 1917: 340). Although these
archaeologists were contemporaries of both Nelson and Gamio, it appears that this
excavation method was largely disregarded (Browman and Givens 1996; Lucas 2001).
Archaeologists of the period appeared to prefer the Arbitrary method of excavation as it
was simpler to employ and because the visible layers of stratification evident in North
and Latin America tended to be the result of natural geological processes rather than
anthropogenic processes (Browman and Givens 1996).
Nevertheless, in more recent American archaeological excavation guidance literature,
excavation via natural stratigraphy is increasingly advised whenever possible (Hester et
al., 1997). Although, as Lucas (2001) points out, despite the use of natural stratigraphy
“the layer is still regarded as the primary element of a site; thus features such as pits are
often described as disturbances to the stratigraphy rather than stratigraphy in their own
right (Lucas 2001: 60; Joukowsky 1980: 150-7), which again differentiates the Natural
Stratigraphic Excavation method from the Stratigraphic Excavation method used in the
United Kingdom, Ireland and Continental Europe.
Having discussed the development of archaeological excavation methods and recording
systems in field archaeology, it will be necessary to examine, in the following chapter,
16
how archaeological excavation methods and recording systems have been adapted and
applied to forensic archaeological casework.
21
2.2 The adaptation and application of archaeological methods to
forensic investigations
In order to effectively discuss the background to the application of forensic archaeology
to the investigation of burials and mass graves numerous factors must be considered.
Firstly, one must discuss the various roles and responsibilities that may be allocated to a
forensic archaeologist during the process of a forensic investigation. One must also
evaluate how the differential development of the discipline in the United Kingdom,
Ireland, Australasia and North America has resulted in discrepancies in how the
discipline’s practitioners have come to define the discipline, and the impact that this has
had upon the archaeological excavation methods that they have chosen to adopt.
Finally, one must consider what qualifications and what level of experience a forensic
archaeologist is expected to have gained in order to be qualified to participate in a
forensic investigation.
Crime scene to court
The acceptance and utilisation of forensic archaeologists in criminal investigations of
burials and mass graves has been a relatively recent development (Hunter et al., 1994:
758). Occasions during which forensic archaeologists are requested to participate in a
forensic investigation in the United Kingdom, Ireland and Australasia are relatively
rare, compared with their North American counterparts (Hunter and Cox 2005). This is
largely due to the fact that these regions have lower homicide rates (Blau 2004; Donlon
2009; Skinner and Bowie 2009).
In recent years forensic archaeologists have been increasingly integrated into crime
scene operations. This is due to greater public awareness of the discipline, and the fact
that if a forensic archaeologist is not used, a defence barrister may call upon a forensic
archaeologist to testify that the methodologies utilised were unsuitable, with the aim of
having the evidence that was collected by unspecialised investigators dismissed from
the court proceedings (Hunter and Dockrill 1996: 43).
However, the decision on whether or not to employ a forensic archaeologist in a crime
scene investigation is left to the discretion of the case’s Senior Investigator (Hunter and
22
Cox 2005; Menez 2005). Nonetheless, if a forensic archaeologist is brought in to assist
with a forensic investigation, there are several requirements that the archaeologist must
fulfil.
Firstly, upon arrival at the crime scene the forensic archaeologist must make sure that
their entrance is recorded in the crime scene log (Pepper 2005: 109). Furthermore, due
to the forensic nature of the investigation, the archaeologist must ensure that they are
wearing a disposable crime scene suit and have either brought, or been provided with,
sterile or new equipment in order to prevent contamination (Hunter and Knupfer 1996:
31; Pepper 2005: 177). It is advisable that the forensic archaeologist also has their
sterile equipment photographed prior to starting any investigative work, to satisfy the
court that no cross contamination may have occurred. It is then that the forensic
archaeologist will be briefed by the Senior Investigator. Such briefings usually outline
the background of the case and involve a discussion of what evidence the investigators
believe may be present at the crime scene (Pepper 2005).
If the investigators require the archaeologist to identify the location of a clandestine
grave, the archaeologist will then establish a grid, and then proceed to inspect the site in
order to identify and record the presence of surface indicators associated with the
creation of a grave (Rodriguez and Bass 1985; Killam 2004; Dupras et al., 2006: 38).
There are four types of surface indicators that may be present at an interment site. The
first indicator is changes to vegetation (Hunter and Martin 1996; Killam 2004; Hunter
and Cox 2005: 30). These changes are induced by the process of digging the grave and
placing human remains within it. Depending on the species of plants present at the
gravesite, the increase in nutrients, provided by the decomposition of the body, will
either promote plant growth or retard plant growth on top of and around the grave
(Morse et al., 1983; Killam 2004; Hunter and Cox 2005).
The second indicator is the presence of disturbed soil. Soil disturbances occur due to the
fact that “one can never dig in the ground and put the dirt back exactly as nature had put
it there originally” (Bass and Birkby 1978:6). Such disturbances take the form of colour
or textural differences between the disturbed soil contained within the grave and the
undisturbed soil surrounding it (Morse et al., 1984; Killam 2004; Hunter and Cox 2005:
32; Dupras et al., 2006). Additionally, due to the fact that space is taken up within the
23
grave by the placement of human remains, perpetrators are often left with an excess of
soil after backfilling. Consequently, this soil is often piled on top of the grave resulting
in the creation of a soil mound (Killam 2004; Hunter and Cox 2005: 31).
The third indicator is the presence of depressions on the ground surface. Primary
depressions are triggered by the settlement of soil contained within the grave over the
course of time (Killam 2004; Dupras et al., 2006). This results in the grave’s surface
sinking beneath that of the surrounding undisturbed ground. Secondary depressions are
caused by the collapse of the victim’s abdominal cavity during decomposition (Morse et
al., 1983). When this occurs, the soil that had been resting on top of this cavity falls into
it, resulting in the creation of a small secondary depression on the grave’s surface, over
the area where the victim’s abdomen once was (Killam 2004: 35).
The fourth indicator is the presence of animal activity (Rodriguez and Bass 1985;
Dupras et al., 2006). When human remains are contained within a grave it often attracts
scavengers. These scavengers attempt to gain access to the remains by burrowing into
the grave, resulting in signs of digging around the area in which the grave is located
(Killam 2004: 36; Dupras et al., 2006).
In addition to surface indicators, the forensic archaeologist may also employ
geophysical surveying techniques such as: earth resistivity, magnetometry,
electromagnetic systems, or ground penetrating radar (Bevan 1991; Davenport 2001a;
Davenport 2001b; Killam 2004; Cheetham 2005; Dupras et al., 2006). These techniques
allow the archaeologist to measure and map the properties of the investigative area’s
sub-surface. Such properties include its “acoustic, electrical, magnetic and
electromagnetic” characteristics (Cheetham 2005: 65). It is by identifying regions
within the survey area that have measurably different properties from those surrounding
it that the archaeologist is able to detect possible grave locations. These regions are
commonly referred to as ‘anomalies’ or ‘hot-spots’ (Cheetham 2005: 65).
If any surface indicators or sub-surface anomalies are identified during the search phase
of the investigation they are drawn, photographed and/or videoed, and digitally recorded
using a Total Station, or its technological equivalent (Hunter and Dockrill 1996: 52;
Menez 2005). Moreover, if potential evidentiary artefacts are located they are also
recorded using the same techniques. Once recorded, these artefacts are then signed over
24
to the investigator who is in charge of exhibits, so that they can be packaged and
labelled in the appropriate manner. This ensures that the chain of custody is maintained,
and that the artefactual evidence is admissible in court (Hunter and Cox 2005).
Once potential grave locations have been identified, the forensic archaeologist must
then conduct an invasive evaluation in order to confirm or discount the presence of a
grave. The invasive evaluation involves two steps. The first step is to excavate a test pit,
away from the potential grave locations, in order to evaluate the natural geological
composition of the site (Wright et al., 2005: 147; Congram 2008: 794). The findings
from this test pit will then be used to identify areas in which the natural geology of the
site has been disturbed, potentially due to the excavation and backfilling of a grave.
The second step is to excavate rectangular sondages across the width of each of the
potential graves in order to identify disturbances to the natural geology of the site, and
to locate the presence of human remains (Hunter and Cox 2005). If human remains are
found, the forensic archaeologist can then confirm to the Senior Investigator that they
have identified the grave. It is at this point that the Coroner or Medical Examiner is
notified that human remains have been found, and their permission is requested to
continue the investigation (Hunter and Knupfer 1996; Hunter and Cox 2005).
Having obtained permission to continue, the forensic archaeologist then proceeds to
excavate the grave. There are a variety of approaches to excavating such features.
Practitioners such as Brooks and Brooks (1984), Ubelaker (1989), Spennemann and
Franke (1995), Pickering and Bachman (1997), Haglund et al., (2001), Stover and Ryan
(2001), Oakley (2005), Burns (2006), and Ruwanpura et al., (2006) state that access
trenches should be excavated around the outline of the identified grave cut, and that
excavation should proceed in a series of arbitrarily defined spits, removing both the
material contained within the grave feature and the access trenches surrounding it. Any
human remains or artefacts found during the excavation process should be left upon a
soil pedestal until they have been recorded. Such items can then be removed and
transferred to the relevant processing facility.
Similarly, Bass and Birkby (1978), Morse et al., (1983), and Connor (2007) recommend
that the grave should be excavated in a series of arbitrarily defined spits, and that any
human remains or artefacts uncovered during the excavation should be left upon a soil
25
pedestal. However, unlike the former set of academics they suggest that the grave cut
should be maintained throughout the excavation process.
In contrast, Larson et al., (2011) suggest that a trench should be excavated around the
outline of the grave cut until the bottom of the grave has been reached. The grave
should then be undercut and a forensic platform slid underneath the human remains and
the in situ grave fill. This ‘grave block’ is then transferred into a specially designed
evidence bag and shock-resistant container. The ‘grave block’ is then transported back
to the laboratory and excavated in controlled laboratory conditions.
Unlike the previous academics Hunter and Cox (2005), Dupras et al., (2006), Ruffell et
al., (2009), Litherland et al., (2012), and Hunter et al., (2013) state that the grave should
be excavated using the Demirant Excavation method. When using this method, the
excavation process is contained to within the boundaries of the grave cut. Once the
outline of the grave has been defined, the grave is then divided into two halves, each of
which are excavated separately. Likewise, Hunter (2009) suggests that the grave cut
should be maintained, and that the feature should be divided and excavated following
the Demirant Excavation method. However, he recommends that a baulk, along the
mid-line of the grave, should be left in place until the end of the excavation process.
Alternatively, Congram (2008) recommends that the Quadrant Excavation method be
used. When using this method the grave cut is maintained, but the grave feature is
divided into four different quarters, each of which are excavated separately.
In contrast, Wolfe Steadman et al., (2009) advocate a method in which the grave’s
boundaries are maintained, but the grave’s fill is excavated by vertically slicing through
the fill from one side of the grave to the other. The size of the individual slices is
dependent upon the size of the grave that is being excavated, and is left to the discretion
of the archaeologist.
Conversely, Powell et al., (1997), Connor and Scott (2001), Hunter et al., (2001),
Hochrein (2002), Skinner et al., (2003), Hanson (2004), Blau (2005), Blau and Skinner
(2005), Jessee and Skinner (2005), Skinner and Sterenberg (2005), Schultz and Dupras
(2008), Cheetham and Hanson (2009), and Nuzzolese and Borrini (2010) argue that the
grave should be excavated using the Stratigraphic Excavation method. When using this
26
method, the grave cut is maintained, and each of the fills contained within the grave are
defined and excavated in isolation, in the reverse order of their deposition – “last in =
first out” (Congram 2008: 794).
During the excavation, it is crucial that the forensic archaeologist identifies and records
any geotaphonomic features that may be present. These features are categorised into six
groups: stratification, tool marks, bioturbation, sedimentation, compression/depression,
and internal compaction (Hochrein 1997; Hochrein 2002). Such features can indicate:
the method by which the grave was constructed, whether or not the grave had been left
open prior to the placement of human remains within it, whether or not the
perpetrator(s) stood in the grave when constructing it, whether or not the victim was
alive when placed into the grave, and whether or not the grave has been disturbed by
scavengers during the time period between the human remains interment and
subsequent excavation (Hochrein 1997; Hochrein 2002; Menez 2005; Wright et al.,
2005). Such features can therefore provide evidence to determine whether or not the
crime was pre-meditated, which will have significance when the case goes to court, and
assist the forensic archaeologist in reconstructing the sequence of events that occurred
from the point at which the grave was created up until its excavation (Hunter and Cox
2005; Cox et al., 2008).
In addition to geotaphonomic evidence, the grave may also contain entomological,
toxicological, and botanical evidence. If such evidence is identified, it is best practice to
request assistance from the relevant specialist to ensure that the correct sampling and
collection procedures are adhered to (Dirkmaat and Adovasio 1997; Hunter et al., 2001;
Cox et al., 2008).
In regards to the human remains, once they have been uncovered it is a legal
requirement for a medical professional to declare that “life is extinct” (Pepper 2005:
111). It is also the point at which a forensic pathologist is required to attend the scene in
order to supervise the removal of the human remains and any sampling (Hunter and Cox
2005:6; Pepper 2005: 111). If the remains are skeletonised, a forensic anthropologist
may also be requested to assist with the removal and recording of the skeletal remains
(Hunter et al., 1996; Hunter and Cox 2005: 7).
27
It is essential that the entire excavation process is documented either in written form –
site journals or pre-prepared pro-formas, or in a digital format – digital photographs or
digital videos, preferably both (Dirkmaat and Adovasio 1997; Hunter and Cox 2005;
Pepper 2005; Cheetham et al., 2008). Such records should contain: descriptions of the
stratigraphic contexts associated with the grave, a list of the evidence that was found in
the grave as well as the exact spatial location in which each piece was found, and a plan
of the grave structure (Hunter et al., 1996; Hunter and Cox 2005; Menez 2005; Dupras
et al., 2006). This recording procedure is important, as the process of excavating a grave
is destructive, and the records made during the excavation are the only remaining
evidence of what was contained within the grave, and, provide the means by which the
forensic archaeologist can construct and support their narrative of the sequence of
events that occurred from the point at which the grave was dug to the time at which it
was excavated (Adams and Valdez 1997; Crist 2001; Saul and Saul 2002; Dupras et al.,
2006: 107).
Having completed the excavation the forensic archaeologist will then be required to
write a report. This report will be submitted to the court as evidence. Such reports are
required to:
- Contain the expert’s qualifications, relevant experience and accreditation.
- Provide references of any literature that the expert has relied upon whilst making
the report.
- Contain a statement summarising all of the facts that were given to the expert
which were influential in forming their opinion.
- Outline which of the facts stated in the report are within the expert’s expertise.
- State who carried out any examination, measurement, test, or experiment, which
the expert has used in the report, and provide the qualifications, relevant
experience and accreditation of that person.
- Provide a summary of the expert’s findings.
28
- If there is a range of opinion regarding matters considered in the report, the
expert should summarise these opinions, and give the reasons for their own.
- Contain a summary of the conclusions reached.
- Include a statement which explains that the expert has understood their duty to
the court, and that they have complied and will continue to comply with this
duty throughout the proceedings.
- Include the same declaration of truth as is found in a witness statement.
Having provided the court with the report the forensic archaeologist may then be
required to appear in court as an expert witness. This, however, is dependent upon the
defendant’s plea. If they plead ‘guilty’ the forensic archaeologist’s report will not be
contested in the courtroom (Dilley 2005: 196). Whereas, if the defendant pleads ‘not
guilty’, on the basis that the expert evidence is inaccurate, or the investigation was
mishandled in some manner, then the forensic archaeologist may be required to give
evidence to the court as an expert witness (Dilley 2005: 196). In this role, the forensic
archaeologist must assist the court, including barristers, judges, and juries, to
understand the technical or scientific data contained within their report that the court
deems to be beyond the understanding of the average lay person (Hampton 2004; Dilley
2005; Hunter and Cox 2005). In order to be effective during this process, the forensic
archaeologist must ensure that they are “fully cognisant with the contents of their
report” (Dilley 2005: 197). This will ensure that the forensic archaeologist is able to
present and defend their findings in a convincing and credible manner, during both the
examination-in-chief and cross-examination stages of the court proceedings.
International perspectives
Forensic archaeology can be defined as the practical application of archaeological
methods and theories to aid in the identification, investigation and interpretation of sites
of legal interest (Killam 2004; Oakley 2005; Dupras et al., 2006: 5; Cox et al., 2008:
216). Most often, forensic archaeological work is focused upon the recovery of human
remains (Rainio et al., 2001; Jankauskas et al., 2005; Gojanović and Sutlović 2007;
Komar and Buikstra 2008; Borić et al., 2011). However, in recent years, the discipline’s
29
practitioners have become involved in criminal investigations that have sought to
recover buried stolen goods, weaponry, and ransom money (Oakley 2005; Cheetham
and Hanson 2009). Forensic archaeologists have also assisted in civil investigations in
which land boundaries have been under dispute (Pers. Comm. P. Cheetham 2012). It is
through involvement in such cases that the discipline of forensic archaeology has
become widely accepted as a specialist forensic discipline, both domestically and
internationally.
However, despite the discipline’s wide scale acceptance within the forensic community,
differences in terms of the origins and subsequent development of the discipline
internationally, have resulted in discrepancies in how its practitioners have come to
define the sub-field of forensic archaeology and the manner in which they have utilised
archaeological methodologies during the process of a forensic investigation.
It was in North America where the beneficial application of archaeological techniques
and theories to forensic investigations was first recognised by anthropologists such as:
Krogman (1943), Morse et al., (1976), and Snow (1982) who highlighted how the
application of archaeological methodologies to the excavation and recording of graves
would result in a better understanding of the grave’s formation process and a greater
rate of evidence recovery. As with traditional archaeology, universities providing
training facilities in forensic archaeology in North America are subsumed under the
auspices of anthropology departments, resulting in individuals training in the field of
forensic anthropology to regard themselves as “cross-trained between physical
anthropology and archaeology” (Scott and Connor 2001: 101).
The extent to which the discipline has developed in North America can be gauged by
the fact that North American forensic anthropologists have become increasingly
involved in homicide investigations, particularly in cases where investigators are
attempting to locate and recover buried human remains (Dupras et al., 2006; Connor
2007; Schultz and Dupras 2008; Skinner and Bowie 2009; Larson et al., 2011).
Moreover, such practitioners are now included in the majority of State and Federal mass
disaster teams, and have assisted in recovery operations such as: the World Trade
Centre investigation in New York in 2001, and the Rhode Island night club fire
investigation in 2003 (Blau 2005).
30
Due to the increase in interest in forensic anthropology and archaeology universities
such as: the University of Montana, Texas State University, Boston University, the
University of Tennessee, the University of Florida, the University of Indianapolis,
Adelphi University, Mercyhurst Archaeological Institute, St. Mary’s University, the
University of Toronto, the University of Windsor, and Simon Fraser University have
developed courses specialising in forensic archaeology and anthropology. Furthermore,
forensic archaeology field schools have been developed by establishments such as
Florida State University and the American Academy of Forensic Sciences (AAFS) in
conjunction with local law enforcement departments in order to train police
investigators in forensic archaeological techniques (Crist 2001; Hunter et al., 1996: 21;
Schultz and Dupras 2008).
Notably, North American forensic anthropologists are not only being used domestically.
Due to the recognition of the discipline’s capabilities in regards to the recovery of
human remains, numerous organisations have been founded including: Physicians for
Human Rights (PHR) in 1986, Necrosearch International in 1991, the International
Commission on Missing Persons (ICMP) in 1996, and the POW/MIA Accounting
Command (JPAC) in 2002, all of whom employ forensic anthropologists to recover the
remains of missing persons, whether it be working in collaboration with organisations
such as the United Nations, as was seen with the use of North American forensic
anthropologists in the missing persons recovery operations during the International
Criminal Tribunal for the Former Yugoslavia (ICTY) and the International Criminal
Tribunal for Rwanda (ICTR), or recovering the remains of American soldiers who have
been killed in action (Hunter and Cox 2005; Juhl 2005; Dupras et al., 2006; Skinner and
Bowie 2009: 94).
Similarly, in the United Kingdom and Ireland, forensic archaeological expertise has
been “increasingly utilised in the search, location and recovery of materials associated
with buried crime scenes” (Oakley 2005: 170; Ruffell et al., 2009; Davenport and
Harrison 2011). Unlike North America, forensic archaeology in the United Kingdom
and Ireland is not regarded as a sub-discipline of forensic anthropology, but as a
discipline in its own right, concerned primarily with excavation and field skills (Hunter
et al., 1996; Hunter and Cox 2005; Blau and Ubelaker 2009). Thus, when forensic
archaeologists are invited to partake in forensic investigations, they are first and
31
foremost archaeologists, rather than physical anthropologists (Scott and Connor 2001).
Forensic archaeology’s widespread acceptance in the United Kingdom owes much to
the discipline’s formal accreditation by the Council for the Registration of Forensic
Practitioners (CRFP), allowing for its acceptance amongst other forensic fields that
have long been utilised in forensic investigations (Ebsworth 2000; Kershaw 2001).
However, since the CRFP’s disbandment in 2009, formal accreditation of the discipline
and its practitioners has been transferred to the Institute for Archaeologists Forensic
Archaeology Special Interest Group, which was formed in 2011, which accredits its
members according to their experience, publications and qualifications.
The increase in awareness of the discipline of forensic archaeology also resulted in the
formation of university post-graduate courses at: Bournemouth University, Cranfield
University, the University of Bradford, and University College London, each of which
focus on training individuals in the principles and practices of forensic archaeology
(Menez 2005). In addition, increasing involvement of forensic archaeologists in
criminal investigations dealing with the recovery of human remains has resulted in the
integration of forensic archaeological methods into the basic training programmes of
Police Search Advisors (POLSA) and Crime Scene Investigators (CSI) (Hunter and Cox
2005: 6).
The presence of forensic archaeological expertise in the United Kingdom and Ireland
has also led to the formation of organisations such as: the Centre for International
Forensic Assistance (CIFA) in 2001, and the International Centre of Excellence for the
Investigation of Genocide (INFORCE) in 2001. Both of these organisations employ
forensic archaeologists to assist with the recovery of human remains in investigations of
human rights abuses, war crimes, genocide, and mass disasters (Hunter and Cox 2005:
23; Cox 2009: 32).
In Australasia, the situation is somewhat different. Despite Australian forensic
archaeologists becoming involved in the international investigations of mass graves at
Serniki (1990) and Ustinovka (1991) in the Ukraine (Wright 1995), and in domestic
contexts such as the search for Samantha Knight (McDonald 1999) and the exhumation
of Sally Anne Huckstepp (Donlon 2009), and universities such as: James Cook
University, the University of Adelaide, Flinders University, the University of
Queensland, the University of New England, and the Australian National University
32
offering degree programmes in forensic archaeology (Colley 2004; Donlon 2009), the
expertise of forensic archaeologists in domestic cases is relatively underutilised as an
investigative tool in Australia, New Zealand, New Guinea and the surrounding Pacific
Islands (Blau 2004; Blau 2005; Oakley 2005; Pers. Comm. R. Wright 2011). Moreover,
the discipline of forensic archaeology is also yet to be recognised by the Senior
Managers of Australian and New Zealand Forensic Laboratories (SMANZFL) and its
associated Scientific Advisory Group (SAG) (Donlon 2009; Pers. Comm. S. Blau
2011). However, in the relatively few cases in which Australasian practitioners have
been invited to assist in forensic investigations, forensic archaeologists and forensic
anthropologists have been utilised separately (Pers. Comm. R. Wright 2011).
Despite the underutilisation of forensic archaeology in Australasia, the discipline’s
practitioners have established an organisation known as Australian – Forensic
Archaeology Recovery (Aus-FAR) in 2003, whose members provide forensic
archaeological expertise when required (Blau 2005: 20). Additionally, Australian
forensic archaeologists have become involved in the creation of Australian Disaster
Victim Identification (DVI) programmes and have been added to their list of mass
disaster responders. This has resulted in Australian forensic archaeologists becoming
involved in disaster recovery operations such as: the Bali Bombings in 2002, and the
Thailand Tsunami in 2004 (Blau 2005).
Due to the differential development and categorisation of forensic archaeology
internationally, it is evident that practitioners have come to define their roles within
forensic investigations differently, resulting in a variety of approaches being utilised
during the recovery of human remains in forensic contexts. Tuller and Đurić (2006) and
Congram (2008) have argued that those individuals whom classify themselves as
forensic anthropologists and archaeologists, such as in North America, tend to be body-
centric in their approach to the excavation of human remains, as their primary goal is to
retrieve the remains in order to establish an accurate biological profile and determine
the manner and the cause of the individual’s death.
In contrast, in the United Kingdom, Ireland and Australasia, where practitioners define
the sub-field of forensic archaeology as a separate speciality, and are employed solely
as forensic archaeologists, their approach to the excavation of a forensic grave differs
(Thompson 2003; Menez 2005). Scholars such as Hanson (2004), Tuller and Đurić
33
(2006) and Congram (2008) state that such practitioner’s primary focus during the
excavation is to understand the grave’s formation process in order to interpret and
reconstruct the sequence of human activity surrounding the grave’s construction, during
which human remains form a part of the material evidence collected, and are viewed as
a depositional event within the overall sequence of the grave’s formation process
(Connor and Scott 2001; Saul and Saul 2002; Tuller and Đurić 2006).
Qualifications and experience
As a consequence of participating in a forensic investigation a forensic archaeologist
may be required to appear in a court as an expert witness (Dilley 2005; Pepper 2005). In
such circumstances, the forensic archaeologist will have to demonstrate to the court that
they have gained enough experience and relevant qualifications in the sub-field of
forensic archaeology to qualify to be considered as an expert by the court (Hunter et al.,
1996; Dilley 2005).
In terms of the appropriate level of experience and qualifications that a forensic
archaeologist should have in order to participate within a forensic investigation and
qualify as an expert witness in court, scholars are unanimous in their claims that a
forensic archaeologist should have gained at least an undergraduate degree in
archaeology or anthropology, and be an experienced field archaeologist (Sigler-
Eisenberg 1985; United Nations 1991; France et al., 1992; Spennemann and Franke
1995; Crist 2001; Hunter et al., 2001; Wright et al., 2005; Cox et al., 2008; Cheetham
and Hanson 2009). Such qualifications and experience, they argue, will ensure that
when a forensic archaeologist is called upon to participate within a forensic
investigation they will be able to successfully evaluate, adapt and implement
excavations in a variety of contexts rapidly, and record as second nature (Connor and
Scott 2001; Hunter and Cox 2005).
However, despite statements claiming that archaeological and anthropological
qualifications and experience are vital components in defining a forensic archaeologist’s
competence, and determining if they are suitably qualified to be deemed as an expert by
the court, little research has been conducted to gauge how much experience a forensic
archaeologist must have in order to become sufficiently experienced to ensure an
effective and complete recovery of all of the forensic evidence present at a crime scene
34
(Haglund 2001; Kershaw 2001; Hunter and Cox 2005; Cheetham and Hanson 2009;
Cox 2009). There are a few references within the literature that refer to the need for
forensic archaeologists to have ‘many years experience’ (Sigler-Eisenberg 1985;
Haglund 2001; Hunter and Cox 2005) but only Scott and Connor (2001) quantify the
amount, stating that in order to be deemed as a capable practitioner the forensic
archaeologist should have at least “3 years full-time fieldwork experience” (Scott and
Connor 2001: 104). Within organisations such as the American Academy of Forensic
Sciences (AAFS), other forensic disciplines such as forensic engineering and
criminalistics have set levels of experience required for a candidate to be accepted as an
associate member, ranging from 4-5 years with a baccalaureate degree, 3-4 years with a
masters degree, and 2-3 years with a doctorate (AAFS 2012). As yet, no such standards
exist for the forensic anthropology section (AAFS 2012). However, currently, in the
United Kingdom, the Institute for Archaeologists Forensic Archaeology Special Interest
Group is in the process of developing a rank system for forensic archaeological
practitioners, based upon their level of experience and qualifications.
In a legal context, as experience is regarded as one of the key factors in establishing
oneself as a credible expert witness, the current lack of a quantified and internationally
agreed upon level of experience necessary for a forensic archaeologist to be recognised
as a capable practitioner may have serious ramifications in terms of the admissibility of
a forensic archaeologist as an expert witness in a court of law (Cheetham and Hanson
2009; NAS Report 2009).
In order to fully understand these ramifications, it will be necessary to discuss, in the
following chapter, the admissibility regulations and the legislative requirements of the
international courts, and the impact that these have on the disciple of forensic
archaeology.
2.3 Legal concerns: How international legislation and
admissibility regulations impact forensic archaeological
investigations
In order to appreciate the impact that international admissibility regulations and
legislative requirements have on forensic archaeological investigations, it is necessary
35
to examine a number of factors. Firstly, one must examine the domestic legislative acts
and the admissibility regulations that are currently in use in the countries involved in the
study, including: the United Kingdom, Ireland, Australia, New Zealand, Canada and the
United States. In addition, as forensic archaeologists are also employed in international
contexts, to aid in the investigation of genocide, crimes against humanity, war crimes,
and crimes of aggression, it is necessary to consider the legislative acts and the
admissibility regulations upheld by the International Criminal Court (ICC), and the
impact that these have on the work undertaken by forensic archaeologists. Finally, one
must evaluate whether or not current forensic archaeological practice meets the
admissibility and legislative requirements of these different legal systems, and if not,
how this impacts the status of forensic archaeology as an accepted forensic discipline.
Domestic contexts
When forensic archaeologists are called upon to participate in forensic investigations
within domestic contexts, there a number of legislative acts and admissibility
regulations in place which influence how forensic archaeological investigations are
conducted, and outline what is expected of forensic archaeologists when acting in the
capacity of an expert witness during court proceedings.
The major legislative acts and admissibility regulations that are currently in place within
the various domestic courts of the countries involved in the study are as follows:
- The Police and Criminal Evidence Act (1984), the Criminal Justice Act (2003),
the Criminal Evidence (Experts) Act (2011), and the Criminal Procedure Rules
(2011) in England and Wales.
- The Criminal Procedure (Scotland) Act (1995), and the Criminal Justice
(Scotland) Act (2003) in Scotland.
- The Criminal Evidence Act (Northern Ireland) (1923), the Police and Criminal
Evidence Act (1984), and the Criminal Justice (Evidence) (Northern Ireland)
Order (2004) in Northern Ireland.
- The Criminal Justice (Forensic Evidence) Act (1990), and the Rules of the
Superior Courts (Evidence) (2007) in Ireland.
36
- The Criminal Procedure Ordinance (1993), the Evidence Act (1995), the
Evidence Amendment Act (2008), and the Practice Note CM7 Expert Witnesses
in Proceedings in the Federal Court of Australia (2009) in Australia.
- The Evidence Act (2006), the Practice Notes – Expert Witness – Code of
Conduct (2011), and the Criminal Procedure Act (2011) in New Zealand.
- The Canada Evidence Act (1985), the Criminal Code (1985), and the Federal
Court Rules – SOR/98-106 in Canada.
- The Frye Standard (1923), the Daubert Standard (1993) and the Federal Rules of
Evidence (2011) in the United States.
These domestic admissibility regulations and legislative acts establish five key
requirements that must be considered by the court to determine if the expert testimony
and the evidence retrieved by the forensic archaeologist during the course of the
forensic archaeological investigation can be deemed as reliable, and therefore
admissible in the court.
Empirical testing
The first requirement is whether the techniques that were used by the forensic
archaeologist during the course of the forensic investigation have been empirically
tested. Currently, little testing has been done in the field of archaeology, or forensic
archaeology, to comparatively assess the various excavation methods and recording
systems utilised by forensic archaeologists to excavate burials. The only significant
experimental research that has been conducted in this area thus far has been completed
by Tuller and Đurić (2006), Pelling (2008), and Evis (2009), each of whom
comparatively assessed two different excavation methods – Arbitrary and Stratigraphic
excavation using mass graves or grave simulations. However, these studies failed to use
large enough sample sizes to thoroughly compare these two excavation methodologies,
and failed to compare archaeological recording systems (Tuller and Đurić 2006; Pelling
2008; Evis 2009). Another weakness of these studies is that they failed to test other
excavation methodologies, such as the Demirant Excavation method and the Quadrant
Excavation method, each of which have been used by practitioners in forensic casework
37
(Hunter and Cox 2005; Dupras et al., 2006; Congram 2008; Hunter 2009; Ruffell et al.,
2009). As a result, these three studies should be regarded as pilot studies that need to be
expanded upon by further experimental research. Therefore, currently, forensic
archaeologists should not state to the court that the methodological approaches that they
used to excavate and record a forensic burial have been thoroughly tested, and as a
result, the court could deem these methodological approaches as potentially unreliable,
and consequently inadmissible.
Peer review
The second requirement is whether the techniques that were used by the forensic
archaeologist have been subjected to peer review and have been published. Within the
discipline of forensic archaeology and archaeology, numerous scholars have published
articles, books, and archaeological manuals discussing excavation methods and
recording systems, including: Phillips et al., (1951), Wheeler (1954), Pallis (1956),
Kjolbye-Biddle (1975), Harris (1979), Joukowsky (1980), Barker (1993), Hester (1997),
Roskams (2001), Hanson (2004), Balme and Paterson (2006), Burns (2006), Blau and
Ubelaker (2009), and Carver (2009) to name but a few. However, depending on their
own personal preferences, training and experience different scholars advocate and
publish different methodological approaches. Therefore, if a forensic archaeologist was
to justify their methodological approach to the court by referring to publications, they
would be able do so, as a number of excavation methods and recording systems have
been published and peer reviewed. However, the fact that there is no standardised and
widely accepted methodological approach for the excavation and recording of burials,
could arguably weaken forensic archaeologists attempts to demonstrate to the court that
the techniques that they used during the forensic investigation were reliable, and thus
admissible.
Error rates
The third requirement is whether the techniques that were used by the forensic
archaeologist have known or potential rates of error. As stated earlier, due to the fact
that there has been very little testing of archaeological excavation methods and
recording systems, there are no published error rates for individual excavation methods
and their associated recording systems. This means that this requirement has not yet
38
been met by the discipline of forensic archaeology. Consequently, forensic
archaeological techniques could be deemed by the court to be potentially unreliable, as
there is no data to suggest otherwise, and lead to the forensic archaeologist’s testimony
and evidence collected as a result of their participation in the investigation being
dismissed from the court proceedings.
Professional standards
The fourth requirement is whether the techniques that were used by the forensic
archaeologist have standards controlling their operation, and whether these standards
were maintained during the course of the forensic investigation. In terms of an accepted
standardised protocol for domestic forensic archaeological investigations, the only
organisation that has created one is the Institute for Archaeologists Forensic
Archaeology Special Interest Group in the United Kingdom, who published ‘Standards
and Guidance for Forensic Archaeologists’ in October of 2011 (Powers and Sibun
2011).
This document outlines a protocol for forensic archaeologists to follow when
conducting forensic archaeological investigations in the United Kingdom. However, in
terms of providing a standardised methodological approach for the excavation and
recording of clandestine burials, this guidance document is vague, stating that “features
are investigated and excavated using the archaeological technique most suited to the
specific circumstances of the case” (Powers and Sibun 2011: 16) and that the “forensic
archaeologist must undertake all excavation with the aim of maintaining stratigraphic
integrity, maximise the recovery of evidence, carrying out in situ evidence recording,
and ensure that the details of the scene are reproducible through the production of
written, illustrative and photographic records” (Powers and Sibun 2011: 16). This
guidance document, therefore, does not provide any specific procedures for the
excavation and recording of clandestine graves, and merely reiterates statements
outlined in text books dedicated to the discipline of forensic archaeology (Hunter and
Cox 2005; Dupras et al., 2006, Connor 2007; Blau and Ubelaker 2009).
As this guidance document fails to outline a specific excavation and recording protocol
for forensic archaeological investigations, it provides forensic archaeologists in the
United Kingdom with the freedom to excavate using any archaeological approach that
39
has been used previously, or that has been published, and does not provide specific
standards for forensic archaeologists to follow when conducting a forensic
archaeological investigation. Furthermore, as not one of the archaeological excavation
methods and recording systems that are published and used by forensic archaeologists
to excavate and record clandestine burials have been thoroughly tested, these
methodological approaches and this guidance document do not satisfy the requirements
of the British or international courts.
The fact that no other domestic forensic archaeological organisations, working in the
other geographical regions covered by this study, have attempted to create standard
protocols for forensic archaeological investigations also means that, in international
contexts, the discipline of forensic archaeology is failing to meet the fourth requirement
for admissibility (Law Commission 2011). This could result in the findings and
testimonies of forensic archaeologists being deemed as inadmissible and dismissed from
court proceedings.
Widespread acceptance
The fifth requirement is whether the techniques that were used by the forensic
archaeologist have gained widespread acceptance within the particular field to which
they belong. As with the second requirement, several scholars have published and
advocated a variety of different archaeological approaches to the excavation and
recording of clandestine burials (Bass and Birkby 1978; Pickering and Bachman 1997;
Haglund et al., 2001; Hunter et al., 2001; Skinner et al., 2003; Hunter and Cox 2005;
Burns 2006; Dupras et al., 2006; Connor 2007; Congram 2008; Cheetham and Hanson
2009; Hunter 2009; Wolfe Steadman et al., 2009; Larson et al., 2011). The approaches
that they recommend vary according to when and where they received their training and
experience, and their own personal preferences. Furthermore, many of the techniques
that these scholars advocate originate from field archaeology and have been used for a
long period of time, and continue to be used on a regular basis within the commercial
archaeology sector. Thus, if a forensic archaeologist was required to prove that the
techniques that they used during the forensic investigation were widely accepted within
the field of archaeology, they would be able to provide many examples to attest to the
fact that they were.
40
However, as with the second requirement, the fact that all of the methodological
approaches that are currently used within the field of archaeology and forensic
archaeology are generally accepted, as long as the selection of each approach is
justified, may in turn, weaken a forensic archaeologist’s attempts to highlight to the
court that the technique that they chose was the most reliable and suitable to use. This is
because there is no data, as yet, from which a forensic archaeologist can reliably state
that one methodological approach is more reliable and consistent than another, and
therefore, the forensic archaeologist may find that their testimony is regarded with
caution, due to the potential for the technique that they chose to be unreliable.
The primary reason why forensic archaeology has, to date, remained unaffected by the
legislative requirements and admissibility regulations set by domestic courts was
recently highlighted in a review of expert evidence conducted by the Law Commission
which stated that “expert evidence is often trusted like no other category of evidence”
(The Law Commission 2011:12) and “cross-examining advocates tend not to probe, test
or challenge the underlying basis of an expert’s opinion evidence” (The Law
Commission 2011:13) as they “do not feel confident or equipped to challenge the
material underpinning the expert opinion” (The Law Commission 2011:13), leading to
forensic archaeologists and the methods they utilise remaining unquestioned in a court
environment.
However, in light of recent reviews of expert evidence conducted in the United States,
Canada, Australia and the United Kingdom (Australian Law Reform Commission 2005;
Glancy and Bradford 2007; Edwards 2009; NAS Report 2009; The Law Commission
2009, 2011; Robertson 2009; Edmond 2010; Robertson 2010; Selby 2010),
admissibility regulations are now being increasingly enforced and expert witnesses and
the legal practitioners with whom they are working are now required to prove, prior to
appearing in court, that the methods used by the forensic archaeologist during the
course of a forensic investigation meet the admissibility requirements of the court. If the
forensic archaeologist or the legal practitioner fails to do so, the evidence gathered by
the forensic archaeologist in support of the case will be deemed unreliable and
dismissed from the court proceedings (NAS Report 2009; The Law Commission 2009,
2011). This is illustrated by the case of Hunter v. United States, 48F. Supp. 2d 1283,
1288 (D. Utah 1998) during which the government sought to prosecute Hunter for
41
defacing the Santa Clara River Gorge Shelter site in the Dixie National Forest and
looting other archaeological sites (Hutt 2006). Two archaeologists were commissioned
to assess the damage to the site and estimate how much it would cost to repair and
restore the site back to its former state, and in turn, how much Hunter would be required
to pay in damages (Hutt 2006). However, the two reports contradicted each other, and
the Judge presiding over the case stated that the methods used by each of the
archaeologists in order to complete their archaeological site damage assessment reports
“lack[ed] sufficient reliability to be used for sentencing purposes” (ID. At 1291.) (Hutt
2006). Consequently, both of the reports that had been submitted as evidence by the two
archaeologists were dismissed from the court proceedings, and were not taken into
consideration by the judge when he calculated the amount of damages that the
defendant would have to pay towards the archaeological site’s restoration (Hutt 2006).
International contexts
In addition to domestic investigations, forensic archaeologists are also requested to
assist in investigations in international contexts. Such investigations require forensic
archaeologists to assist in the search, location, recovery and recording of evidence from
scenes of crime relating to genocide, crimes against humanity, war crimes, and crimes
of aggression. Currently, investigations into these four types of crime are conducted
under the auspices of the International Criminal Court (ICC). Prior to the establishment
of the ICC in 2002, after the ratification of the Rome Statute, investigations of these
crimes were conducted and prosecuted by International Criminal Tribunals, such as the
International Criminal Tribunal for the Former Yugoslavia (ICTY) and the International
Criminal Tribunal for Rwanda (ICTR) (Kittichaisaree 2001; Cordner and McKelvie
2002; Cox et al., 2008).
Unlike the domestic court systems discussed previously, the ICC does not follow an
adversarial system of justice. Rather, it uses a hybrid system, of adversarial and
inquisitorial systems, utilising the strengths of both approaches to investigate crimes
under its jurisdiction. Under this hybrid system, it is important to note that there is no
jury; instead, professional judges are elected to preside over the trial, determining the
weight of the evidence brought before them and the sentence that ought to be given to
the accused. As a result, the judges who preside over such trials are not required to act
42
as “gate keepers against bad science” on behalf of juries, as their professional training
and experience ought to provide them with the ability to consider each piece of
evidence that has been presented to them, and ascertain the weight that it ought to be
given (Roberts and Willmore 1993; Schabas 2006; Klinkner 2008; 2009). Therefore, the
ICC does not have strict procedures or rules governing the admissibility of evidence or
expert witness testimonies, and tends to follow an approach of “admit everything,
determine weight later” (Zahar and Sluiter 2008: 384; Klinkner 2009).
There are however, ‘Rules of Procedure and Evidence’ that are followed by the ICC,
which state in Rule 64 that “evidence that is ruled irrelevant or inadmissible shall not be
considered by the Chamber” (The International Criminal Court 2013: 21). Therefore, if
the methodological approaches utilised by forensic archaeologists during the course of
the investigation are proved to be unreliable, then the evidence retrieved by the forensic
archaeologists and the testimony provided by the forensic archaeologist in charge of the
investigation, would then lack relevance to the case and be deemed inadmissible, and
ought not to be considered by the trial chamber when determining the sentence of the
accused. However, as there have been relatively few studies focused on evaluating the
reliability of forensic archaeological excavation methods and recording systems, there is
no data for the defence or prosecution to use to critique or defend the methodological
approaches used by forensic archaeologists during such investigations (Klinkner 2009).
This issue is exacerbated by the fact that when forensic archaeologists are called to
participate in such investigations they are employed by the prosecution, and are directed
by the prosecution’s senior investigator in all operational matters (Klinkner 2009). At
no stage during this investigative process are the defence’s forensic archaeological
experts given the opportunity to observe or conduct independent investigations at these
scenes of crime. Given that excavation is a destructive process, and once a grave, be it a
mass or single grave, has been excavated it cannot be re-excavated, any operational
errors in terms of methodological or recording processes cannot be observed at the
scene, and any evidence that may have contradicted the prosecution’s report’s findings
will have been lost during the investigative process (Barker 1993). Therefore, the
current system of providing the defence with the prosecution’s forensic archaeological
report post-facto to review and critique clearly has a flaw, as issues that may have gone
unnoticed or were overlooked by the prosecution’s team during the investigation will
43
not be present in the report. Thus, the defence’s forensic archaeological experts will not
have the entire picture of the investigative process, and will not be able to evaluate it
fully.
This issue also applies to the court’s process of employing independent experts to
evaluate reports provided by the prosecution in cases where the defence and prosecution
disagree over evidential reliability matters, as they too will only be able to review the
‘polished’ end of investigation report. Given that such investigations are planned over a
long period of time, the fact that courts are aware of whom they wish to prosecute, and
the vast amount of money that is invested in investigating these crime scenes, it would
be beneficial and possible for the court to inform the defence of when and where
forensic archaeological investigations are to take place, and to invite them to send
defence forensic archaeological experts to observe these investigations as they take
place. This will ensure that they, the defence, are satisfied that the evidence that is
collected and recorded is being done so in a reliable manner.
Furthermore, as with the domestic legal systems, the reliance on the cross-examining
advocates’ and the professional judges’ experience to highlight and evaluate the
reliability of the methods used by experts during the course of an investigation poses a
problem. Given the vast array of different forensic disciplines that are required to assist
with such investigations and present evidence in ICC trials, these legal practitioners
cannot be expected to have gained sufficient experience and knowledge in each of these
disciplines to be able to effectively evaluate each discipline’s methodological
approaches to determine if they are reliable enough to be admitted (Roberts and
Willmore 1993; Boas 2001; Klinkner 2009; The Law Commission 2011:13). Moreover,
as there are no admissibility requirements in place, current procedure does not demand
that methods be shown to be reliable before they are admitted. Thus, each judge may
use different evaluative criteria when assessing the admissibility of particular methods,
which may result in judges having contradicting opinions as to whether a particular
methodological approach was appropriate (Boas 2001: 59). This may explain why, to
date, the “reliability of particular scientific methods and techniques appears to be more
fully canvassed as a question of weight, rather than admissibility” and highlights why
the methodological approaches of disciplines such as forensic archaeology, have
remained unquestioned during trials at the International Criminal Court and
44
International Criminal Tribunals for the Former Yugoslavia and Rwanda (Boas 2001:
59).
It is evident, through reviewing the admissibility regulations and the legislative
requirements of courts in both domestic and international contexts that forensic
archaeology has, to date, failed to satisfy the requirements of the international court
systems. This is primarily due to the fact that practitioners in the sub-field of forensic
archaeology have yet to test the methodological approaches that they use and advocate.
This has resulted in a multitude of excavation methods and recording systems
continuing to be used without any proof that they produce consistent and accurate
results. Furthermore, the fact that there is no internationally agreed upon, standardised,
peer-reviewed protocol for forensic archaeological investigations, weakens the
credibility of the sub-field, as it implies that there is a lack of professionalism within the
discipline, and that its practitioners use ad hoc approaches during forensic
investigations. Consequently, the court systems discussed in this Project should not
allow evidence retrieved through excavation by forensic archaeologists into their courts.
Therefore, if the discipline of forensic archaeology is to continue to be accepted as a
forensic discipline, these weaknesses must be addressed, otherwise, forensic
archaeologists’ testimonies and the evidence that they collect during the course of a
forensic investigation may be dismissed from the court proceedings as the
methodological approaches underpinning the investigation were deemed unsafe,
potentially unreliable, and therefore inadmissible.
In light of these issues, it will be necessary to evaluate, in the following chapter,
previous research that has been undertaken to test forensic archaeological excavation
methods and recording systems, and to discuss how such research can be improved
upon in order to ensure that the discipline of forensic archaeology continues to be
accepted by the international courts.
2.4 The search for standardisation in forensic archaeological
investigations
In order to evaluate how the discipline of forensic archaeology has attempted to address
the issue of the lack of empirical testing of archaeological excavation methods and
45
recording systems. One must first evaluate existing research that has been conducted
into archaeological excavation methods and recording systems. After which, one needs
to discuss how this research can be improved upon and expanded in order to ensure that
the discipline of forensic archaeology meets the admissibility regulations and the
legislative requirements of the international court systems.
Testing of archaeological techniques
The process of controlled excavation is perhaps the most common aspect of
archaeology with which archaeologists are associated. The process of “excavation is the
prime method available to archaeologists for the recovery of new data” (Clarke
1978:63), whereas the process of recording provides the only current means of
preserving the new data obtained through the excavation activity. It is universally
accepted that the excavation and recording of sites, be it in archaeological or forensic
contexts, by competent personnel with adequate facilities represents both the most
important and best means of acquiring additional information (Clarke 1978; Sigler-
Eisenberg 1985; Haglund 2001; Scott and Connor 2001; Hunter and Cox 2005).
However, excavation methods and recording systems have, to a large extent, developed
independently from one another, each evolving to their current state according to the
intellectual, technical, and theoretical developments within the discipline, and the
professional and ethical codes of practice advocated by professional bodies such as: the
Institute for Archaeologists (IfA) in the United Kingdom, the Institute of Archaeologists
of Ireland (IAI) in the Republic of Ireland, the Society for American Archaeology
(SAA) in the United States, the Canadian Archaeological Association (CAA) in Canada,
the Australian Archaeological Association (AAA) in Australia, and the New Zealand
Archaeological Association (NZAA) in New Zealand. Consequently, different
combinations of excavation methods and recording systems are utilised by different
archaeological practitioners, in accordance with their individual preferences,
experience, academic training, and the legislative requirements present within the
geographical area in which they are working.
Therefore, numerous practitioners advocate different excavation methods and recording
systems as the works of Phillips et al., (1951), Wheeler (1954), Pallis (1956), Kjolbye-
Biddle (1975), Harris (1979), Joukowsky (1980), Barker (1993), Roskams (2001),
46
Harris (2006) and Carver (2009) demonstrate. However, as different excavation
methods such as: the Stratigraphic method, the Schnitt method, the Gezer method, the
Quadrant method, the Arbitrary method, and the Box method, and different recording
systems such as: Single Context Recording, Multi-Context Recording, Unit Level
Recording, and Pre-determined Strata Recording continue to be utilised and advocated
(along with their theoretical justifications) within academic literature these different
techniques have come to be attributed the status of ‘standardised methods’ within the
countries, traditions, schools and institutes in which they are practiced (Kidder and
Kidder 1917; Fowler 1977; Daniel 1978; Willey and Sabloff 1980; Joukowsky 1980;
Bar-Yosef and Mazar 1982; Browman and Givens 1996; Hester 1997; Lymen and
O’Brien 1999; Darvill 2000; Drewett 2000; Lucas 2001; Collis 2002; Desert
Archaeology, 2008; Greene and Moore 2010).
Although a variety of excavation techniques and recording systems have been allocated
the status of a “standardised method” the suitability of certain excavation methods and
recording systems have been called into question and sparked debate within the
academic community (see Phillips et al., 1951; Harris 1989; Harris et al., 1993 for an
overview). However, little research has been conducted to directly measure, contrast
and compare differing excavation methods and recording systems, or to understand the
impact that variations in approaches to excavation and recording may have on data
recovery and interpretation(s). This is largely because no two archaeological sites are
exactly alike and the excavation of an archaeological site cannot be replicated, as the
process of excavation is one of destruction. Methods cannot, normally, be tested and
compared on the same set of deposits, although there are examples of archaeological
sites that have been re-excavated and the findings of previous archaeological
investigations re-evaluated – Ian Hodder’s work in Çatalhöyük and the re-excavation of
the ‘Lazete 2’ Srebrenica mass grave site being two prominent examples (Çatalhöyük
2011; ICTY 2007).
Additionally, in recent experimental research conducted by Tuller and Đurić (2006),
Pelling (2008), and Evis (2009) it is apparent that the assumption that excavation
methods are suitable for use on the basis of their widespread adoption and
‘standardised’ status should be called into question and re-evaluated.
47
Each of these experimental studies directly compared two standardised excavation
methods – the Arbitrary Excavation method and the Stratigraphic Excavation method.
In Tuller and Đurić’s (2006) study they compared these two excavation methods in the
excavation and recovery of skeletal remains within two mass graves in an attempt to
identify which method was the most effective. Their results established that the
Stratigraphic method of excavation was the most effective at maintaining the
provenience and articulation of the remains. However, each grave was excavated by
differing teams of experts, one consisting of archaeologists and the other of a mix of
pathologists and biological anthropologists, and therefore was not an objective or direct
comparison of each methodological approach (Tuller and Đurić 2006).
In Pelling’s (2008) study, the primary aim was to define which of these two methods
was the most effective at recovering ‘evidence’ from simulated graves which included:
artefacts, geotaphonomic features and stratigraphic deposits and interfaces. Pelling’s
study found the Stratigraphic method of excavation to be the most effective and resulted
in 94.4% of material evidence placed within the grave being recovered in situ, whereas
50% of material evidence was found in situ using the Arbitrary Excavation method
(Pelling 2008). In addition, the Stratigraphic approach recovered 100% of
geotaphonomic features introduced into the grave whereas the Arbitrary approach failed
to recover any (Pelling 2008). However, Pelling’s (2008) study only simulated one
grave for each method and therefore was not a large enough sample size to effectively
compare these methodological approaches.
In light of this, Evis (2009) conducted a similar experiment to Pelling and created eight
mock graves in order to assess which of these two excavation methods was the most
effective at correctly interpreting the graves’ formation sequence and recovering
‘evidence’ which, again, included: artefacts, geotaphonomic features, and stratigraphic
deposits and interfaces. Evis enlisted four archaeologists to excavate two graves each
(Evis 2009). The results of the study indicated that the Stratigraphic Excavation method
was the most effective, recovering an average of 71% of all defined evidence types,
whereas the Arbitrary Excavation method recovered an average of 56% (Evis 2009). In
terms of consistency of interpretation of the graves formation sequence, again the
Stratigraphic method of excavation proved to have a higher rate of consistency,
correctly identifying an average of 71% of the deposits and interfaces present and an
48
average of 62.5% of the geotaphonomic features introduced into the graves, whereas the
Arbitrary Excavation method correctly identified an average of 51% of the deposits and
interfaces present and an average of 12.5% of the geotaphonomic features (Evis 2009).
In addition, through conducting the experiment with multiple archaeologists it became
apparent that additional variables may have affected the percentage of evidence
recovered and the consistency of subsequent interpretations. Factors such as experience
and time caused variation in the results gained, findings which were supported by
experiments conducted by Tuller and Đurić (2006), Scherr (2009) and Roberts (2009).
However, this study only compared four graves for each methodological approach and
therefore was not a large enough sample size to effectively compare these two
excavation methods. Furthermore, the experiment only compared two excavation
methods and therefore did not take into account or test all of the published
methodological approaches used in the field of archaeology. Also, the experiment did
not assess the affect of variables such as sight, sound, touch and smell which could have
had an influence on the overall findings.
Improvement and expansion of existing research
Because of the limitations of the aforementioned studies they should be regarded as
pilot studies that need to be expanded upon through further research and
experimentation. Moreover, not one of the discussed studies comparatively assessed
archaeological recording systems. This is an important aspect of the archaeological
process not to have investigated, as the records produced during the course of an
excavation will provide the evidence from which the archaeologist will construct and
justify their narrative of how the archaeological feature or site under investigation was
formed. Therefore, the impact that different recording systems may have on the overall
representation and interpretation of an archaeologist’s findings is as yet unknown, and
must also be addressed through further research and experimentation.
This Project aimed to complete such tasks by increasing the sample size and increasing
the number of methodological approaches assessed. It also comparatively assessed
recording systems to determine whether different approaches had any impact on the
representation and subsequent interpretation of archaeological data. It is also recognised
that archaeological excavation and recording is a highly perceptual skill and can be
49
affected by a number of extrinsic factors. However, an evaluation of these factors was
outside the remit of this Project.
Despite the limitations of the previous studies their findings have significant
implications for the field of archaeology, as the processes of excavation and recording
provide the raw data to which theories are applied and interpretations are formed. If
certain excavation methods and recording systems and additional influential variables
are proven to result in the loss of contextual information, artefacts, features or deposits,
then any interpretations based on assemblages excavated and recorded via these
methods may be incomplete, or at least subject to different interpretation. Subsequently,
any individuals reading the interpretations may be mislead and the results potentially
misused, one needs only to refer to the ‘Ahnenerbe’ and the ‘Amt Rosenberg’
organisations in Nazi Germany to highlight this point (Arnold 1990; Arnold 1996;
Pringle 2006). Members of these archaeological organisations focused their
investigations on proving Gustaf Kossinna’s ‘Kulturkreis Theory’ which stated that
geographical regions could be associated with specific ethnic groups based on the
presence of material culture, and that cultural diffusion was a process whereby
influences and ideas were passed on by more advanced societies to the less advanced
societies with whom they came into contact (Arnold 1996:550). As a result, “wherever a
single find of a type designated as Germanic was found the land was declared ancient
German territory” (Sklenář 1983:151), thus providing the theoretical justification for the
Nazi’s expansion into Czechoslovakia and Poland, as it was deemed that the Nazis were
claiming back their ancient ancestral heritage (Arnold 1990; Arnold 1996; Pringle
2006). Moreover, in a forensic context, it could result in a perpetrator not being
convicted or the wrongful conviction of an innocent individual (Gould 2007; Cheetham
and Hanson 2009).
It was therefore important for this Project to be undertaken as it empirically tested the
excavation and recording techniques currently used in the field of archaeology and
resulted in the formulation of bespoke recommendations for archaeological
investigations conducted in forensic contexts. The development of this Project was
timely, as it was directly responding to the latest legislative requirements of the
international courts, and will help to ensure that archaeologists and the evidence
retrieved as a consequence of their involvement in a forensic investigation will meet the